Compact optical module including multiple active components and path changer component
An optical module includes a housing, a plurality of active optical components and a path changer component. The housing has an airtight chamber. The active optical components are provided in the airtight chamber. The path changer component is provided in the airtight chamber, and the path changer component is configured to change an optical path of at least one of the active optical components.
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This application claims priority under 35 U.S.C. § 119(a) on Patent Application No(s). 202210132834.2 filed in China on Feb. 14, 2022, the entire contents of which are hereby incorporated by reference.
BACKGROUND 1. Technical FieldThe present disclosure relates to optical communication, more particularly, an optical module in optical communication.
2. Related ArtOptical modules are generally installed in communication facilities in modern high-speed communication networks. With the improvement of optical communication system and the increase in demand of broad bandwidth by various network services, insufficient internal space and high energy consumption of the conventional optical modules should be overcome. Any solution to provide optical modules with small size, large amount of internal space for accommodation, and low energy consumption while enhancing bandwidth and transmission speed has been one of the important topics in this technical field.
SUMMARYAccording to one aspect of the present disclosure, an optical module includes a housing, a plurality of active optical components and a path changer component. The housing has an airtight chamber. The active optical components are provided in the airtight chamber. The path changer component is provided in the airtight chamber as well, and is configured to change an optical path of at least one of the active optical components.
In the following detailed description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the disclosed embodiments. According to the description, claims and the drawings disclosed in the specification, one skilled in the art may easily understand the concepts and features of the present disclosure. The following embodiments further illustrate various aspects of the present disclosure, but are not meant to limit the scope of the present disclosure.
According to the present disclosure, an optical module including housing, active optical component and path changer component is provided. Please refer to
The housing 10 may include a header (stem) and a cap for TO-can package. The housing 10 may have an airtight chamber 110 and a window 120 spatially connected with the airtight chamber 110. The active optical components 20 and the path changer component 30 are accommodated in the airtight chamber 110, and one of the active optical components 20 may be coaxially aligned with the window 120 of the housing 10.
Furthermore, the optical module 1a may include a carrier 40 and a ceramic feedthrough 50. The carrier 40 may be accommodated in the airtight chamber 110 of the housing 10, and the ceramic feedthrough 50 may be partially disposed within the housing 10, which represents that part of the ceramic feedthrough 50 is accommodated in the housing 10 and another part thereof exposes to outside. The carrier 40 may be a metallic heat sink carrying the active optical components 20 and the path changer component 30, and the carrier 40 may be configured to help heat dissipation of the active optical components 20. The ceramic feedthrough 50 may be fixed to the housing 10 by solder sealing 60, and the ceramic feedthrough 50 may be electrically connected with one or more active optical components 20 by wire bonding. The implementation of electrical signal transmission for the active optical components 20 by the ceramic feedthrough 50 can meet the requirements of high bandwidth and low RF loss.
In this embodiment, optical module 1a may further include a solder ring 2, a metallic sleeve 3, an optical isolator 4, a coupling lens 5 and a fiber ferrule 6. The solder ring 2 may be provided on the outer surface of the housing 10. The metallic sleeve 3 may be inserted into the solder ring 2 for preventing the electromagnetic interference. The optical isolator 4 may be accommodated in the housing 10, and the coupling lens 5 and the fiber ferrule 6 may be accommodated in the metallic sleeve 3. The optical isolator 4, the coupling lens 5 and the fiber ferrule 6 are configured to facilitate the optical coupling between the active optical components 20 and an optical fiber 7.
Details of the active optical components 20 and the path changer component 30 are described hereafter. As shown in
In some other embodiments, the active optical component can generate or receive optical signals suitable for long distance transmission. The wavelength of the optical signals mentioned herein may refer to a peak in a spectral linewidth, and said optical signals in different wavelengths may refer to at least two different peaks.
The path changer component 30 may be accommodated in the airtight chamber 110 of the housing 10, and the path changer component 30 may be configured to change an optical path of at least one of the active optical components 20. In this embodiment, the path changer component 30 can change an optical path of light received by the optical receiver 20B.
As shown in
The oblique prism 320 may have two light passing surfaces 321 which are substantially orthogonal to the optical path RX of the optical receiver 20B, and two optical surfaces 322 which are inclined with respect to the optical path RX of the optical receiver 20B. The optical surface 312 of the right-angle prism 310 may be attached to one of the optical surfaces 322 of the oblique prism 320. The light passing surfaces 321 of the oblique prism 320 might allow for the light within the wavelength of 1330 nm to pass through while the optical surface 322 might reflect the light toward the optical receiver 20B. As such, the light might be received by the optical receiver 20B. The light passing surface 321 might be associated with high transmittance for the optical signals to be traveling toward the optical receiver 20B. Consequently, external optical signals transmitted by the optical fiber 7 can enter into the optical module 1a and travel through the light passing surface 321, then can be reflected by the optical surfaces 322 twice before being received by the optical receiver 20B. In short, the optical path RX might be turned two times. The light passing surface 321 and the optical surface 322 of the oblique prism 320 might allow light emitted by the optical transmitter 20A within the wavelength of 1270 nm to pass through. The term “high transmittance” mentioned herein refers to the transmittance that meets the requirements for optical signal transmission. For example, a transmittance of at least 95% may be defined as high transmittance in order to achieve relevant technical effects for optical communication applications.
In this embodiment, allowing the light within specific wavelength (e.g., 1270 nm or 1330 nm) to pass through the light passing surface 311 might require the optical surface 312 and the light passing surface 321 to be equipped with a filter film on each of the light passing surface 311 and the optical surface 312, with the filter film capable of 95% or more in transmittance for specific wavelengths. Also, an exemplary means for reflecting the light within the specific wavelength (e.g., 1330 nm) at the optical surface 322 may be enabled by providing a filter film on the optical surface 322, where such filter film has a reflectivity of 99% or more for a specific wavelength.
Referring to
Referring further to
According to the embodiment depicted in
According to one embodiment of the present disclosure, the active optical components may include a combination of two optical transmitters.
In this embodiment, the optical transmitter 20A coaxially aligned with the optical fiber 7 can generate optical signals within the wavelength of 1270 nm, and the optical transmitter 20C non-coaxially aligned with the optical fiber 7 can generate optical signals within the wavelength of 1330 nm. The path changer component 30 can change an optical path of the light emitted by the optical transmitter 20C. The light passing surface 311 and the optical surface 312 of the right-angle prism 310 might allow for the light emitted by the optical transmitter 20A within the wavelength of 1270 nm to pass through. The light passing surfaces 321 of the oblique prism 320 might allow for the light emitted by the optical transmitter 20C within the wavelength of 1330 nm to pass through, and the optical surfaces 322 might reflect the light emitted by the optical transmitter 20C (1330 nm). The light passing surface 321 and the optical surface 322 of the oblique prism 320 meanwhile might allow for the light emitted by the optical transmitter 20A (1270 nm) to pass through.
Referring to
By using the path changer component 30 to change the direction of the optical path TX′ for the optical signals generated by optical transmitter 20C, the optical signals generated by the optical transmitter 20C might still be coupled into the optical fiber 7. Therefore, the optical design with the path changer component 30 allows for the optical module 1b to be accommodated using both conventional hermetic package design and dual-emission bidirectional design. For example, the optical module 1b can be using a TO-can package in which the optical transmitter 20A and the non-coaxial optical transmitter 20C are provided.
According to one embodiment of the present disclosure, the active optical components may include a combination of two optical receivers.
In this embodiment, the optical receiver 20B coaxially aligned with the optical fiber 7 can receive and respond to optical signals within the wavelength of 1270 nm, and the optical receiver 20D non-coaxially aligned with the optical fiber 7 can receive and respond to optical signals within the wavelength of 1330 nm. The path changer component 30 can change an optical path of the light traveling toward by the optical receiver 20D. The light passing surface 311 and the optical surface 312 of the right-angle prism 310 might allow for the light traveling toward the optical receiver 20B within the wavelength of 1270 nm to pass through. The light passing surfaces 321 of the oblique prism 320 might allow for the light traveling toward the optical receiver 20D within the wavelength of 1330 nm to pass through, and the optical surfaces 322 might reflect the light traveling toward the optical receiver 20D (1330 nm). The light passing surface 321 and the optical surface 322 of the oblique prism 320 might allow for the light traveling toward the optical receiver 20B (1270 nm) to pass through.
Referring to
By the path changer component 30 to change the optical path RX′, the optical receiver 20D can receive external optical signals. Therefore, the optical design with the path changer component 30 might allow for the optical module 1c to be fabricated by using conventional hermetic package design as well as dual-receiving bidirectional type. For example, the optical module 1c can be fabricated using a TO-can package in which the optical receiver 20B and the optical receiver 20D are provided simultaneously.
As to some communication systems such as data centers and fiber-to-home (FTTH) equipment, to improve signal transmission efficiency and transmission distance always come with the increased production cost in connection with conventional optical modules and much larger overall volume. More specifically, due to harsh outdoor environment for long distance transmission, the optical modules tend to be designed in airtight package. However, the hermetic package suffers many restrictions on the configuration inside the optical modules. For example, multiple optical fibers cannot be coupled with single optical module due to size limitations. Therefore, the conventional optical modules with hermetic package are mostly unidirectional optical modules (that is, a single optical fiber could only transmit or receive the optical signals) to meet commercial demand for compact optical modules and low production cost. However, as the optical modules have gradually evolved toward being smaller in size and higher in data rate, it is difficult to further improve functions of unidirectional optical modules amid increasing demand for bidirectional optical modules with hermetic package.
According to the present disclosure, the path changer component is helpful to design a bidirectional optical module with hermetic package. For example, the configuration of the optical module in the present disclosure can include a TO-can package which generally accommodates either single optical transmitter or single optical receiver in addition to multiple active optical components. The active optical components may include a combination of one optical transmitter with one optical receiver, a combination of two optical transmitters, or a combination of two optical receivers.
Moreover, some optical components, such as wavelength division multiplexer (WDM) or duplexer, may be used for optical path design and multiplexing in a conventional bidirectional optical module, while these optical components may occupy space around the optical module. In contrast, the path changer component and the active optical components (optical transmitters and/or optical receivers) are integrated into a package housing of the optical module disclosed herein, which helps to not only meet the requirement of compactness but also enjoy lower production cost than a configuration including package housing and at least one of WDM and duplexer.
It will be apparent to those skilled in the art that various modifications and variations can be made to the present disclosure. It is intended that the specification and examples be considered as exemplary embodiments only, with a scope of the disclosure being indicated by the following claims and their equivalents.
Claims
1. An optical module, comprising:
- a housing having an airtight chamber;
- a plurality of active optical components provided in the airtight chamber;
- a path changer component provided in the airtight chamber, the path changer component being configured to change an optical path of at least one of the active optical components; and
- wherein the path changer component comprises an oblique prism, the oblique prism has two first light passing surfaces substantially orthogonal to the optical path of the at least one of the active optical components and two first optical surfaces inclined with respect to the optical path, the two first light passing surfaces of the oblique prism allow for light within a first wavelength to pass through, and the two first optical surfaces of the oblique prism reflect light within the first wavelength, wherein the path changer component further comprises a right-angle prism, the right-angle prism has a second light passing surface substantially orthogonal to the optical path of the at least one of the active optical components and a second optical surface inclined with respect to the optical path, the second light passing surface of the right-angle prism allows light within a second wavelength different from the first wavelength to pass through, and the second optical surface of the right-angle prism is attached to one of the first optical surfaces of the oblique prism and allows for light within the second wavelength to pass through.
2. The optical module according to claim 1, wherein the housing comprises a cap for TO-can package.
3. The optical module according to claim 2, further comprising a carrier and a ceramic feedthrough, wherein the carrier is provided in the airtight chamber and carries the active optical components and the path changer component, and the ceramic feedthrough is partially provided within the housing.
4. The optical module according to claim 3, wherein the ceramic feedthrough is fixed to the housing by solder sealing.
5. The optical module according to claim 1, wherein at least one of the active optical components is coaxially aligned within a window of the housing.
6. The optical module according to claim 1, wherein each of the active optical components is configured to emit light with a wavelength of 1270 nm or more, or respond to light received within a wavelength of 1270 nm or more.
7. The optical module according to claim 1, wherein the active optical components comprise at least one of a combination of single optical transmitter with single optical receiver, a combination of two optical transmitters, or a combination of two optical receivers.
8. The optical module according to claim 1, wherein the active optical components comprises an optical receiver to correspond the oblique prism and an optical transmitter to correspond the right-angle prism, the optical receiver responds to light received within the first wavelength, the optical transmitter is configured to emit light within the second wavelength, and the oblique prism is configured to change an optical path of light received by the optical receiver.
9. The optical module according to claim 1, wherein the active optical components comprises two optical transmitters provided to correspond the oblique prism and the right-angle prism, respectively, the two optical transmitters are configured to emit light within the first wavelength and the second wavelength, respectively, and the oblique prism is configured to change an optical path of light emitted within the first wavelength.
10. The optical module according to claim 1, wherein the active optical components comprises two optical receivers provided to correspond the oblique prism and the right-angle prism, respectively, the two optical receivers are configured to respond to light received within the first wavelength and the second wavelength, respectively, and the oblique prism is configured to change an optical path of light received within the first wavelength.
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Type: Grant
Filed: Jul 1, 2022
Date of Patent: Jul 30, 2024
Patent Publication Number: 20230258887
Assignee: Global Technology Inc. (Ningbo)
Inventors: Dong-Biao Jiang (Ningbo), Jian-Hong Luo (Ningbo), Fu Chen (Ningbo), Xiang Zheng (Ningbo)
Primary Examiner: Agustin Bello
Application Number: 17/856,181
International Classification: H04B 10/00 (20130101); G02B 6/42 (20060101); H04B 10/40 (20130101);